Litcius/Paper detail

Deep reinforcement learning for active flow control in a turbulent separation bubble

Bernat Font, Francisco Alcántara-Ávila, Jean Rabault, Ricardo Vinuesa, O. Lehmkuhl

2025Nature Communications40 citationsDOIOpen Access PDF

Abstract

The control efficacy of deep reinforcement learning (DRL) compared with classical periodic forcing is numerically assessed for a turbulent separation bubble (TSB). We show that a control strategy learned on a coarse grid works on a fine grid as long as the coarse grid captures main flow features. This allows to significantly reduce the computational cost of DRL training in a turbulent-flow environment. On the fine grid, the periodic control is able to reduce the TSB area by 6.8%, while the DRL-based control achieves 9.0% reduction. Furthermore, the DRL agent provides a smoother control strategy while conserving momentum instantaneously. The physical analysis of the DRL control strategy reveals the production of large-scale counter-rotating vortices by adjacent actuator pairs. It is shown that the DRL agent acts on a wide range of frequencies to sustain these vortices in time. Last, we also introduce our computational fluid dynamics and DRL open-source framework suited for the next generation of exascale computing machines.

Topics & Concepts

GridTurbulenceMomentum (technical analysis)Forcing (mathematics)Reinforcement learningVortexBubbleComputer scienceFlow (mathematics)Flow control (data)Reduction (mathematics)Control (management)MechanicsControl theory (sociology)Artificial intelligencePhysicsMathematicsParallel computingGeometryAtmospheric sciencesComputer networkFinanceEconomicsFluid Dynamics and Turbulent FlowsLattice Boltzmann Simulation StudiesPlasma and Flow Control in Aerodynamics